Control device, startup method, and electric apparatus

ABSTRACT

A control device includes a processor and a first storage portion. The processor executes a control process based on data stored in a main memory. The first storage portion stores a first memory image related to the main memory after a process of starting-up an operating system by the processor is completed. The control device loads the first memory image into the main memory if the operating system is started up.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.17/126,804, filed Dec. 18, 2020, which is based upon and claims thebenefit of priority from Japanese Patent Application No. 2020-105420,filed on Jun. 18, 2020, the entire contents of each of which areincorporated herein by reference.

FIELD

Embodiments described herein relate generally to a control device, astartup method, and an electric apparatus.

BACKGROUND

In an electric apparatus whose operation is controlled by a controldevice equipped with a processor, hibernation for quickly returning toan operating state immediately before the power of the electricapparatus is turned off is already known. However, after the power ofthe electric apparatus is turned on, the processor is started, and thena process for recovery by hibernation is executed. Therefore, only apart of the start-up time required from turning on the power of theelectric apparatus to being able to use the electric apparatus isshortened. Under those circumstances, it has been desired to reduce thetime required to start the processor.

DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram illustrating a schematic configuration of amultifunction device according to an embodiment and a main circuitconfiguration of a control device;

FIG. 2 is a flowchart of a boot loader; and

FIG. 3 is a flowchart of an operating system.

DETAILED DESCRIPTION

An object to be solved by the present disclosure is to provide a controldevice, a starting method, and an electric apparatus capable ofshortening the time required for starting a processor.

In general, according to one embodiment, a control device includes aprocessor and a first storage portion. The processor executes a controlprocess based on data stored in a main memory. The first storage portionstores a first memory image related to the main memory after a processof starting-up an operating system by the processor is completed. Thecontrol device loads the first memory image into the main memory if theoperating system is started up.

Hereinafter, an example of an embodiment will be described withreference to the drawings. In this embodiment, a multifunction devicewill be described as an example of an electric device. FIG. 1 is a blockdiagram illustrating a schematic configuration of a multifunction device100 according to the embodiment and a main circuit configuration of acontrol device 1. The multifunction device 100 includes the controldevice 1, a reading unit 2 (e.g., a scanner), an image forming unit 3(e.g., a printer), an operation panel 4, a communication unit 5, and apower supply unit 6. The multifunction device 100 may include anotherdevice such as an IC card reader.

The control device 1 controls various devices provided in themultifunction device 100, such as the reading unit 2, the image formingunit 3, the operation panel 4, and the communication unit 5. That is,the control device 1 sets the multifunction device 100 as a controltarget device. The reading unit 2 reads an image formed on a medium,such as paper, and generates image data. As the reading unit 2, variouswell-known reading devices such as a flatbed scanner and an autodocument feeder (ADF) scanner can be used alone or in combination.

The image forming unit 3 forms an image on a medium such as paper basedon the image data generated by the reading unit 2, the image datareceived by the communication unit 5, or the image data generated by thecontrol device 1. As the image forming unit 3, various well-known imageforming devices such as a device that utilizes an electrophotographicmethod of printing or a device with that utilizes an inkjet method ofprinting can be used alone or in combination.

The operation panel 4 (e.g., a user interface) includes an input unit, adisplay unit, and a sound unit. The input unit receives an instructionfrom an operator. As the input unit, various well-known input devicessuch as a touch panel and a key switch can be used alone or incombination. The display unit executes a display operation for notifyingan operator of various information. As the display unit, variouswell-known display devices such as a liquid crystal display or a lightemitting diode (LED) lamp can be used alone or in combination. The soundunit outputs various sounds for guidance and alarms. As the sound unit,various well-known sound devices such as a voice synthesis device or abuzzer can be used alone or in combination.

The communication unit 5 executes communication processing forcommunication via a communication network 200. The communication network200 is, for example, a local area network (LAN). In this case, as thecommunication unit 5, various well-known communication devices for LANcan be used. However, as the communication network 200, various othernetworks such as the Internet, a virtual private network (VPN), a localarea network (LAN), a public communication network, or a mobilecommunication network may be used. As the communication unit 5, a deviceadapted to the communication network 200 may be used. The power supplyunit 6 receives the electric power supplied from the commercial powersource and generates the operating electric power for various electricdevices provided in the multifunction device 100.

The reading unit 2, the image forming unit 3, the operation panel 4, andthe communication unit 5 are examples of devices to be controlled by thecontrol device 1. The reading unit 2, the image forming unit 3, theoperation panel 4, and the communication unit 5 may include a device tobe controlled by the control device 1. For example, the reading unit 2may include an automatic document conveyance device, and this automaticdocument conveyance device may be the control target of the controldevice 1. Further, for example, the image forming unit 3 may include afinisher and this finisher may be the control target of the controldevice 1. A device (not illustrated) such as the IC card readerdescribed above, which may be included in the multifunction device 100and is connected to the control device 1, may also be controlled by thecontrol device 1.

The control device 1 includes a processor 11, a main memory 12, anauxiliary storage unit 13, a device interface 14, and a transmissionline 15. The processor 11, the main memory 12, the auxiliary storageunit 13, and the device interface 14 can communicate with each other viathe transmission line 15. Accordingly, the processor 11, the main memory12, and the auxiliary storage unit 13 are connected by the transmissionline 15, so that a computer for controlling the control device 1 isconfigured.

The processor 11 corresponds to the central part of the computerdescribed above. The processor 11 executes information processing forrealizing various functions of the control device 1 according to aninformation processing program such as an operating system, firmware, oran application program. The processor 11 is, for example, a centralprocessing unit (CPU).

The main memory 12 corresponds to the main memory portion of thecomputer. The main memory 12 includes a non-volatile memory area and avolatile memory area. The main memory 12 stores the above-describedinformation processing program in the non-volatile memory area. The mainmemory 12 may store data necessary for the processor 11 to executeinformation processing in a non-volatile or volatile memory area. Themain memory 12 uses a volatile memory area as a work area in which datais appropriately rewritten by the processor 11. The non-volatile memoryarea is, for example, a read only memory (ROM). The volatile memory areais, for example, a random access memory (RAM).

The auxiliary storage unit 13 corresponds to the auxiliary storageportion of the computer described above. As the auxiliary storage unit13, for example, a storage unit using a well-known storage device suchas an electric erasable programmable read-only memory (EEPROM), a harddisk drive (HDD), or a solid state drive (SSD) can be used alone or incombination. The auxiliary storage unit 13 stores data used by theprocessor 11 to perform various processes, data created by the processesof the processor 11, and the like. The auxiliary storage unit 13 storesthe information processing program described above.

Various devices provided in the multifunction device 100, such as thereading unit 2, the image forming unit 3, the operation panel 4, and thecommunication unit 5, are connected to the device interface 14. Thedevice interface 14 executes communication processing for exchangingdata with each of the connected devices under the control of theprocessor 11. As the device interface 14, for example, a well-knowndevice compliant with the universal serial bus (USB) standard can beused. Further, as the device interface 14, a well-known device compliantwith the wireless LAN standard may be used to exchange data with variousdevices by wireless communication. Further, as the device interface 14,a well-known interface device compliant with the peripheral componentinterconnect express (PCIe) standard can be used. The device interface14 may be provided with a plurality of types of interface devices, and aplurality of devices to be connected to the control device 1 may beconnected separately. The transmission line 15 includes an address bus,a data bus, a control signal line, or the like, and transmits data andcontrol signals transmitted and received between each connected unit.

The control device 1 is configured by mounting the processor 11, themain memory 12, the auxiliary storage unit 13, and the device interface14 on a printed circuit board on which the transmission line 15 isformed, for example. The processor 11, the main memory 12, the auxiliarystorage unit 13, and the device interface 14 may be fixedly attached tothe printed circuit board by soldering or the like, or may be detachablyattached to a socket or slot attached to the printed circuit board. Forexample, the RAM included in the main memory 12 may be installed in amemory slot attached to a printed circuit board and made replaceable.

A part of the storage area of the auxiliary storage unit 13 is used as aboot loader area ARA, an operating system (OS) area ARB, image areas ARCand ARD, an application area ARE, an image area ARF, and a flag areaARG. The OS area ARB, the image areas ARC and ARD, the application areaARE, and the image area ARF are set as separate partitions, for example.

The boot loader area ARA stores the boot loader. The OS area ARB storesthe operating system. This operating system may be any of the variousexisting operating systems. The image areas ARC and ARD respectivelystore first hibernation images described below. The application area AREstores an application program described regarding control processing forcontrolling various devices to be controlled. The image area ARF storesa second hibernation image described below. The flag area stores animage flag described below.

Next, the operation of the multifunction device 100 configured asdescribed above will be described. The operations for realizing variousfunctions of the existing multifunction device such as the copyfunction, the scanner function, the printer function, and the facsimilefunction may be the same as those of the existing multifunction deviceand the description thereof will be omitted. Then, here, if the power ofthe multifunction device 100 is turned on, the operations related to thestarting-up until the operations for the above-described variousfunctions are started will be mainly described. The contents of thevarious processes described below are examples and it is possible tochange the order of some processes, omit some processes, or add anotherprocess as appropriate. For example, in the following description, inorder to explain the characteristic operation of the embodiment in aneasy-to-understand manner, the description of some processes is omitted.For example, if some error occurs, processing for dealing with the errormay be performed, but a description of such processing is omitted.

The multifunction device 100 is configured as one of a series productgroup including two models with different functional levels. Forexample, the multifunction device 100 can be configured as either aso-called standard function model or a high-performance model.Regardless of which model the multifunction device 100 is configured as,the control device 1 basically has the same hardware configuration.However, the capacity of the RAM included in the main memory 12 maydiffer depending on each model. Also, the revisions supported by thePCIe devices included in the device interface 14 may differ. Themultifunction device 100 differs in at least a part of various devicesto be controlled by the control device 1, such as the reading unit 2,the image forming unit 3, the operation panel 4, and the communicationunit 5, depending on which model is configured. For example, as theimage forming unit 3, in the high-performance model, a device fasterthan the standard function model may be used. Further, various devicesto be controlled by the control device 1 may include an optional device.For example, a large-capacity storage device may be additionallyincluded as a device to be controlled by the control device 1.

In the auxiliary storage unit 13, an operating system common to eachmodel is written in the OS area ARB, for example, when the controldevice 1 is manufactured. In the image area ARC, a first image for thestandard function model is written, for example, when the control device1 is manufactured. In the image area ARD, a first image for thehigh-performance model is written, for example, when the control device1 is manufactured. That is, the stored data for the OS area ARB, and theimage areas ARC and ARD are common to both models.

An application program adapted to each of the standard function modeland the high-performance model is selectively written in the applicationarea ARE, for example, when the control device 1 is manufactured. In theimage area ARF, the memory image of the main memory 12 is written as asecond hibernation image by the processor 11 every time the power of themultifunction device 100 is turned off. An image flag indicating whichof the two first hibernation images is valid is selectively written inthe flag area ARG, for example, if the control device 1 is manufactured.In the case of the embodiment, the image flag is set to represent theimage area ARC if the multifunction device 100 is configured as astandard function model (a first model). The image flag is set torepresent the image area ARD if the multifunction device 100 isconfigured as a high-performance model (a second model). That is, thestored data for the application area ARE and the flag area ARG aredifferent between the two models.

The multifunction device 100 after factory shipment may be remodeled dueto maintenance work. In this case, as part of the maintenance work, theprocessor 11 rewrites the application program in the application areaARE, and the image flag in the flag area ARG under the instruction of anoperator.

The first hibernation image is a memory image of the main memory 12 whenthe processor 11 completes the startup process of the operation based onthe operating system. Therefore, the first hibernation image may changeaccording to the hardware configuration of the control device 1 but isnot affected by various devices to be controlled by the control device1. Therefore, the first hibernation image is fixedly determinedaccording to the model of the multifunction device 100.

Thus, the image areas ARC and ARD are an example of a first storageportion that stores the first hibernation image as the first memoryimage. It can be said that the auxiliary storage unit 13 provided withthe image areas ARC and ARD is an example of the first storage portion.The image area ARF is an example of a third storage portion which storesthe second hibernation image as the second memory image. It can be saidthat the auxiliary storage unit 13 provided with the image area ARF isan example of the third storage unit. The image flag is an example ofidentification data and the flag area ARG is an example of a secondstorage portion. It can be said that the auxiliary storage unit 13provided with the flag area ARG is an example of the second storageportion.

If the power of the multifunction device 100 is turned on, the powersupply to each part of the multifunction device 100 is started from thepower supply unit 6. In response to this, the processor 11 startsoperation and executes the boot firmware stored in the non-volatilememory area of the main memory 12 or a ROM (not illustrated). The bootfirmware is, for example, a basic input output system (BIOS) or aunified extensible firmware interface (UEFI). The processor 11initializes various devices included in the control device 1 based onthe boot firmware, and then the processor 11 reads the boot loaderstored in the boot loader area ARA of the auxiliary storage unit 13 intothe main memory 12 and starts the execution of the boot loaderseparately from the boot firmware.

FIG. 2 is a flowchart of the boot loader. As ACT 11, the processor 11confirms whether there is the first hibernation image. Then, if it isconfirmed that the first hibernation image is not stored in any of theimage areas ARC and ARD, for example, the processor 11 determines NO andproceeds to ACT 12. As ACT 12, the processor 11 reads the operatingsystem stored in the OS area ARB of the auxiliary storage unit 13 intothe main memory 12.

On the other hand, if it is confirmed that the first hibernation imageis stored in, for example, either of the image areas ARC and ARD, theprocessor 11 determines YES in ACT 11 and proceeds to ACT 13. As ACT 13,the processor 11 confirms whether there are a plurality of firsthibernation images. For example, in the case of the embodiment, if it isconfirmed that the first hibernation image is stored only in either ofthe image areas ARC and ARD, the processor 11 determines NO and proceedsto ACT 14. As ACT 14, the processor 11 loads the first hibernation imagestored in either of the image area ARC or ARD into the main memory.

For example, in the case of the embodiment, if it is confirmed thatthere is a first hibernation image stored in each of the image areas ARCand ARD (i.e., there are a plurality of first hibernation imagesstored), the processor 11 determines YES in ACT 13 and proceeds to ACT15. As ACT 15, the processor 11 selects one of the plurality of firsthibernation images according to predetermined conditions and loads itinto the main memory 12. For example, the processor 11 selects one ofthe image areas ARC and ARD according to the state of the image flagstored in the flag area ARG of the auxiliary storage unit 13, and thenthe processor 11 loads the first hibernation image stored in the imagearea into the main memory 12. By executing the boot loader by theprocessor 11, the computer having the processor 11 as a central partfunctions as a first loading portion which loads the first hibernationimage as the first memory image into the main memory 12.

The processor 11 proceeds to ACT 16 in either case after reading theoperating system in ACT 12 or after loading the first hibernation imagein ACT 14 or ACT 15. As ACT 16, the processor 11 starts the execution ofthe operating system loaded in the main memory 12 separately from theboot loader. Then, the processor 11 ends the boot loader with this.

FIG. 3 is a flowchart of the operating system. If ACT 12 of FIG. 2 isexecuted by the boot loader, the main memory 12 is in an initial stateof execution of the operating system. Therefore, if the processor 11executes the operating system, it first proceeds to ACT 21. As ACT 21,the processor 11 performs a startup process. Details of this startupprocess will be omitted. The startup process causes the main memory 12to be rewritten and its contents are affected by the difference in thehardware configuration of the control device 1. Then, the processor 11proceeds to ACT 22 after this.

On the other hand, if ACT 14 or ACT 15 in FIG. 2 is executed by the bootloader, the main memory 12 is in a state where ACT 21 in FIG. 3 hasalready been completed. Therefore, if the processor 11 executes theoperating system, it proceeds to ACT 22 without performing ACT 21. AsACT 22, the processor 11 confirms whether there is the secondhibernation image. Then, if it is confirmed that the second hibernationimage is not stored in the image area ARF, for example, the processor 11determines NO and proceeds to ACT 23. As ACT 23, the processor 11 readsthe application program stored in the auxiliary storage unit 13 into themain memory 12.

If it is confirmed that the second hibernation image is stored, forexample, in the image area ARF, the processor 11 determines YES in ACT22 and proceeds to ACT 24. As ACT 24, the processor 11 loads the secondhibernation image stored in the image area ARF of the auxiliary storageunit 13 into the main memory 12. Thus, if the processor 11 executes theoperating system, the computer with the processor 11 as the central partfunctions as a second loading portion which loads the second hibernationimage as the second memory image into the main memory 12.

The processor 11 proceeds to ACT 25 in either case after reading theapplication program in ACT 23 or after loading the second hibernationimage in ACT 24. By loading the second hibernation image, theapplication program is read into the main memory 12.

As ACT 25, the processor 11 starts the execution of the control processbased on the application program separately from the operating systembased on the stored data of the main memory 12. In this case, if theprocessor 11 proceeds from ACT 23 to ACT 25, the processor 11 starts thecontrol process based on the application program from the initial state.Further, if the processor 11 proceeds from ACT 24 to ACT 25, theprocessor 11 returns to a control state immediately before the power ofthe multifunction device 100 is turned off last time. Next, theprocessor 11 then shifts to another process.

As described above, the control device 1 stores in advance the memoryimage of the main memory 12 when the processor 11 completes the startupprocess of the operation based on the operating system in the auxiliarystorage unit 13 as the first hibernation image. Next, the boot loaderloads the first hibernation image to the main memory 12 and then startsthe execution of the operating system. As a result, the processor 11 canomit the startup process of the operating system and can complete thestarting-up of the operating system in a shorter time than in the casewhere the startup process is performed. As a result, the time requiredfor the starting-up of the processor 11 can be shortened.

Further, the control device 1 stores in advance the first hibernationimage for the standard function model and the first hibernation imagefor the high function model in the auxiliary storage unit 13. Then, theabove two first hibernation images are selectively loaded depending onwhether the control device 1 is provided in the multifunction device 100of the standard function model or the multifunction device 100 of thehigh-performance model. Therefore, it is not necessary to write thefirst hibernation image according to the model of the multifunctiondevice 100 to the auxiliary storage unit 13 at the time of manufacturingor maintenance, and thus the effort related to manufacturing ormaintenance is reduced.

Further, the control device 1 returns to the control state if the powerof the multifunction device 100 is turned off by loading the secondhibernation image to the main memory if starting the execution of thecontrol process based on the application program. As a result, the timerequired for the starting-up of the processor 11 can be furthershortened.

Further, the control device 1 reads the operating system in the bootloader if none of the first hibernation images is stored in theauxiliary storage unit 13. As a result, a model that does not store thefirst hibernation image in the auxiliary storage unit 13 and executesthe startup process of the operating system every time the power of themultifunction device 100 is turned on can also be lined up in the seriesproduct group.

Further, in the boot loader, if only one first hibernation image isstored in the auxiliary storage unit 13, the control device 1 loads theone first hibernation image. As a result, the control device 1 can beapplied to the multifunction device 100, which is an independent modelthat does not belong to the series product group.

Further, the control device 1 reads the application if the secondhibernation image is not stored in the auxiliary storage unit 13 in theoperation system. As a result, even when the second hibernation is notgenerated because the power of the multifunction device 100 is turnedoff due to an abnormality such as a power cut, the multifunction device100 can be started up normally. It is also possible to enable operationwithout hibernation using the second hibernation image.

This embodiment can be modified in various ways as follows. Only one ofthe first hibernation images is stored in the auxiliary storage unit 13,and if the processor 11 determines YES in ACT 11 of FIG. 2 , theprocessor 11 proceeds to ACT 14 and may not perform ACT 13 and ACT 15.In this case, the auxiliary storage unit 13 does not have to store theimage flag.

The first hibernation image corresponding to each of the three or moremodels may be stored in the auxiliary storage unit 13. In this case,instead of the image flag, data for identifying any of the areas forstoring three or more first hibernation images is stored in theauxiliary storage unit 13. Which of the plurality of first hibernationimages is valid may be determined by the processor 11 by another methodsuch as storing an identifier that identifies each of the plurality offirst hibernation images in the auxiliary storage unit 13 or using ahardware setting switch.

The electrical device to be controlled by the control device 1 may beany device other than the multifunction device. Further, how theplurality of first hibernation images are used properly may bearbitrary. That is, the control device 1 may be mounted on any of aplurality of separate models which do not form a series, for example.

The loading of the second hibernation image to the main memory 12 may beperformed by the boot loader.

While certain embodiments have been described, these embodiments havebeen presented by way of example only, and are not intended to limit thescope of the inventions. Indeed, the novel embodiments described hereinmay be embodied in a variety of other forms; furthermore, variousomissions, substitutions and changes in the form of the embodimentsdescribed herein may be made without departing from the spirit of theinventions. The accompanying claims and their equivalents are intendedto cover such forms or modifications as would fall within the scope andspirit of the inventions.

What is claimed is:
 1. A control device, comprising: a processorconfigured to execute a control process based on data stored in a mainmemory; and an auxiliary memory configured to store: a first memoryimage related to the main memory after a process of starting-up anoperating system by the processor is completed; and a second memoryimage related to the main memory before the control device is turnedoff, the control device being configured to load the first memory imageinto the main memory in response to the operating system being startedup; and the control device being configured to load the second memoryimage into the main memory after the processor starts a process based ondata that is stored within the main memory after the first memory imageis loaded by the control device.
 2. The control device of claim 1,wherein: the auxiliary memory is configured to store identification dataand a plurality of first memory images each differing from one other;and the control device is configured to select one of the plurality offirst memory images stored in the auxiliary memory based on theidentification data, and load the selected first memory image into themain memory.
 3. The control device of claim 2, wherein theidentification data is predetermined based on a model of a multifunctiondevice associated with the control device.
 4. The control device ofclaim 3, wherein: the identification data identifies the multifunctiondevice as either a first model or a second model; and at least one of(a) the second model includes a device that operates faster than adevice of the first model or (b) the second model includes a device thatis not present in the first model.
 5. The control device of claim 1,wherein the control device is incorporated in a multifunction peripheralincluding a plurality of devices.
 6. The control device of claim 5,wherein the plurality of devices include at least one of a scanner or aprinter.
 7. The control device of claim 6, wherein the plurality ofdevices include the scanner and the printer.
 8. The control device ofclaim 5, wherein the plurality of devices include at least two of (a) ascanner, (b) a printer, (c) an operation panel, or (d) a networkinterface.
 9. An electric apparatus, comprising: a control device; and aplurality of devices operating under the control of the control device,the plurality of devices operating under the control of the controldevice including at least two of (a) a scanner, (b) a printer, (c) anoperation panel, or (d) a network interface, and the control deviceincluding: a processor configured to execute a control process based ondata stored in a main memory; and an auxiliary memory configured tostore a first memory image related to the main memory after a process ofstarting-up an operating system by the processor is completed, thecontrol device being configured to load the first memory image into themain memory in response to the operating system being started up. 10.The electric apparatus of claim 9, wherein: the auxiliary memory isconfigured to store: identification data which identifies a hardwareconfiguration that affects the process of starting-up the operatingsystem; and a plurality of first memory images each differing from oneother; and the control device is configured to select one of theplurality of first memory images stored in the auxiliary memory based onthe identification data stored in the auxiliary memory, and load theselected first memory image into the main memory.
 11. The electricapparatus of claim 9, wherein: the auxiliary memory is configured tostore a second memory image related to the main memory before theelectric apparatus is turned off; and the control device is configuredto load the second memory image into the main memory after the processorstarts a process based on data that is stored within the main memoryafter the selected first memory image is loaded by the control device.12. The electric apparatus of claim 9, wherein the plurality of devicesoperating under the control of the control device include the scanner.13. The electric apparatus of claim 9, wherein the plurality of devicesoperating under the control of the control device include the printer.14. The electric apparatus of claim 9, wherein the plurality of devicesoperating under the control of the control device include the scannerand the printer.
 15. The electric apparatus of claim 9, wherein theplurality of devices operating under the control of the control deviceinclude (a) the scanner, (b) the printer, (c) the operation panel, and(d) the network interface.
 16. A startup method for a control devicethat includes (a) a processor which executes a control process based ondata stored in a main memory and (b) an auxiliary memory which stores afirst memory image related to the main memory after a process ofstarting-up an operating system by the processor is completed, thestartup method comprising: loading the first memory image into the mainmemory when the operating system is started up; starting, by theprocessor, execution of the operating system based on stored data withinthe main memory after the first memory image is loaded; accessing asecond memory image related to the main memory that was previouslystored prior to turning the control device off; and loading the secondmemory image into the main memory after starting execution of theoperating system.
 17. The startup method of claim 16, wherein theauxiliary memory stores a plurality of first memory images eachdiffering from one another, the startup method further comprising:selecting one of the plurality of first memory images stored in theauxiliary memory; and loading the selected first memory image into themain memory when the operating system is started up.
 18. The startupmethod of claim 17, further comprising: selecting the one of theplurality of first memory images stored in the auxiliary memory based onidentification data stored in the auxiliary memory, wherein theidentification data identifies a hardware configuration of a devicecontrolled by the control device.
 19. The startup method of claim 18,wherein: the identification data identifies the device controlled by thecontrol device as either a first model or a second model; and at leastone of (a) the second model operates faster than the first model or (b)the second model includes a component that is not present in the firstmodel.
 20. The startup method of claim 16, further comprising executingthe control process to control a plurality of devices, the plurality ofdevices including at least two of (a) a scanner, (b) a printer, (c) anoperation panel, or (d) a network interface.